Speaker
Description
The Mu2e experiment at Fermilab will search for the charged lepton flavor violating (CLFV) process of a neutrinoless muon-to-electron conversion in the field of an aluminum nucleus. Reaching the experiment’s target sensitivity requires precise normalization of the physics signal through accurate monitoring of the muon capture rate on the stopping target.
For this purpose, the Calorimeter Precise High-Resolution Intensity detector (CAPHRI) has been developed. The detector is composed of four LYSO crystals installed in the upstream disk of the Mu2e calorimeter and read out with the standard calorimeter readout. CAPHRI measures the muon capture rate by detecting the characteristic 1.8 MeV gamma emission line of the $^{27}$Al($\mu^-$, $\nu$n$\gamma$) $^{26}$Mg nuclear reaction. The fast, precise response enables injection-by-injection monitoring of proton beam intensity fluctuations.
We report on the commissioning and performance characterization of CAPHRI. The response of each channel is calibrated at two SiPM overvoltages using both the intrinsic self-emission of the LYSO crystals and cosmic ray signals. In parallel, Monte Carlo simulations are used to evaluate the detector acceptance and the expected signal-to-background ratio under realistic running conditions.
Preliminary results show a crystal light yield consistent with expectations and a channel inter-calibration at the 2-4% level. Simulation studies indicate that the detector acceptance and background rejection satisfy the requirements for physics operations, with about 850 detected events per beam injection at a beam power of 1.5 kW.
These results demonstrate that CAPHRI is an effective tool for beam monitoring and signal normalization in Mu2e.